Balloon assembly for valvuloplasty catheter system

ABSTRACT

A catheter system (100) used for treating a treatment site (106) within or adjacent to the heart valve (108) includes an energy source (124), an energy guide (122A), and a balloon assembly (104). The energy source (124) generates energy. The energy guide (122A) is configured to receive energy from the energy source (124). The balloon assembly (104) is positionable substantially adjacent to the treatment site (106). The balloon assembly (104) includes an outer balloon (104B) and an inner balloon (104A) that is positioned substantially within the outer balloon (104B). Each of the balloons (104A, 104B) has a balloon wall (130) that defines a balloon interior (146). Each of the balloons (104A, 104B) is configured to retain a balloon fluid (132) within the balloon interior (146). The balloon wall (130) of the inner balloon (104A) is positioned spaced apart from the balloon wall (130) of the outer balloon (104B) to define an interstitial space (146A) therebetween. A portion of the energy guide (122A) that receives the energy from the energy source (124) is positioned within the interstitial space (146A) between the balloons (104A, 104B) so that a plasma-induced bubble (134) is formed in the balloon fluid (132) within the interstitial space (146A).

RELATED APPLICATION

This application claims priority from U.S. Provisional Application Ser.No. 63/136,474, filed on Jan. 12, 2021. To the extent permitted, thecontents of U.S. Provisional Application Ser. No. 63/136,474 areincorporated in their entirety herein by reference.

BACKGROUND

Vascular lesions, such as calcium deposits, within and adjacent to heartvalves in the body can be associated with an increased risk for majoradverse events, such as myocardial infarction, embolism, deep veinthrombosis, stroke, and the like. Severe vascular lesions, such asseverely calcified vascular lesions, can be difficult to treat andachieve patency for a physician in a clinical setting.

The aortic valve is a valve of the human heart between the leftventricle and the aorta. The aortic valve functions as a one-way valveand typically includes three leaflets which open and close in unisonwhen the valve is functioning properly. During normal operation, whenthe left ventricle contracts (during ventricular systole), pressurerises in the left ventricle. When the pressure in the left ventriclerises above the pressure in the aorta, the aortic valve opens, allowingblood to exit the left ventricle into the aorta. When ventricularsystole ends, pressure in the left ventricle rapidly drops. When thepressure in the left ventricle decreases, the momentum of the vortex atthe outlet of the valve forces the aortic valve to close. Dysfunction orimproper operation of the aortic valve can result in left ventricularhypertrophy (enlargement and thickening of the walls of the leftventricle) and/or aortic valve regurgitation, which is the backflow ofblood from the aorta into the left ventricle during diastole. Suchissues can lead to heart failure if left uncorrected.

A calcium deposit on the aortic valve, known as aortic valve stenosis,can form adjacent to a valve wall of the aortic valve and/or on orbetween the leaflets of the aortic valve. Aortic valve stenosis canprevent the leaflets from opening and closing completely, which can, inturn, result in the undesired aortic valve regurgitation. Over time,such calcium deposits can cause the leaflets to become less mobile andultimately prevent the heart from supplying enough blood to the rest ofthe body.

Certain methods are currently available which attempt to address aorticvalve stenosis, but such methods have not been altogether satisfactory.Certain such methods include using a standard balloon valvuloplastycatheter, and artificial aortic valve replacement, which can be used torestore functionality of the aortic valve. During aortic valvuloplasty,a balloon is expanded at high pressure in the inside of the aortic valveto break apart calcification on the valve leaflets cusps and between thecommissures of the valve leaflets. Usually, this procedure is done priorto placing a replacement aortic valve. Certain anatomical factors suchas heavily calcified valves can prevent the valvuloplasty from beingeffective enough for valve placement, causing performance and safetyconcerns for the replacement valve. In order for the replacement valveto function correctly it must be precisely positioned over the nativevalve. Stated in another manner, aortic valvuloplasty often does nothave enough strength to sufficiently disrupt the calcium deposit betweenthe leaflets or at the base of the leaflets, which can subsequentlyadversely impact the effectiveness of any aortic valve replacementprocedure. Aortic valve replacement can also be highly invasive andextremely expensive. In still another such method, a valvular stent canbe placed between the leaflets to bypass the leaflets. This procedure isrelatively costly, and results have found that the pressure gradientdoes not appreciably improve.

Thus, there is an ongoing desire to develop improved methodologies forvalvuloplasty in order to more effectively and efficiently break upcalcium deposits adjacent to the valve wall of the aortic valve and/oron or between the leaflets of the aortic valve. Additionally, it isdesired that such improved methodologies work effectively to address notonly aortic valve stenosis related to the aortic valve, but alsocalcification on other heart valves, such as mitral valve stenosiswithin the mitral valve, valvular stenosis within the tricuspid valve,and pulmonary valve stenosis within the pulmonary valve.

SUMMARY

The present invention is directed toward a catheter system used fortreating a treatment site within or adjacent to the heart valve within abody of a patient. In various embodiments, the catheter system includesan energy source, an energy guide, and a balloon assembly. The energysource generates energy. The energy guide is configured to receiveenergy from the energy source. The balloon assembly is positionablesubstantially adjacent to the treatment site. The balloon assemblyincludes an outer balloon and an inner balloon that is positionedsubstantially within the outer balloon. Each of the balloons has aballoon wall that defines a balloon interior. Each of the balloons isconfigured to retain a balloon fluid within the balloon interior. Theballoon wall of the inner balloon is positioned spaced apart from theballoon wall of the outer balloon to define an interstitial spacetherebetween. A portion of the energy guide that receives the energyfrom the energy source is positioned within the interstitial spacebetween the balloons so that a plasma-induced bubble (also sometimesreferred to herein as “plasma”) is formed in the balloon fluid withinthe interstitial space.

In some embodiments, the energy guide includes a guide distal end thatis positioned within the interstitial space between the balloons so thatthe plasma-induced bubble is formed in the balloon fluid within theinterstitial space.

In certain embodiments, each of the balloons is selectively inflatablewith the balloon fluid to expand to an inflated state.

In various embodiments, when the balloons are in the inflated state theballoon wall of the inner balloon is spaced apart from the balloon wallof the outer balloon to define the interstitial space therebetween.

In some embodiments, when the balloons are in the inflated state, theouter balloon is configured to be positioned substantially adjacent tothe treatment site.

In certain embodiments, when the balloons are in the inflated state, theinner balloon has an inner balloon diameter, and the outer balloon hasan outer balloon diameter that is greater than the inner balloondiameter of the inner balloon.

In various embodiments, when the balloons are in the inflated state, theouter balloon diameter of the outer balloon is at least approximately 5%greater than the inner balloon diameter of the inner balloon.

In some embodiments, when the balloons are in the inflated state, theouter balloon diameter of the outer balloon is at least approximately10% greater than the inner balloon diameter of the inner balloon.

In certain embodiments, when the balloons are in the inflated state, theouter balloon diameter of the outer balloon is at least approximately20% greater than the inner balloon diameter of the inner balloon.

In some embodiments, when the balloons are in the inflated state, theouter balloon diameter of the outer balloon is at least approximately30% greater than the inner balloon diameter of the inner balloon.

In certain embodiments, when the balloons are in the inflated state, theinner balloon is inflated to a greater inflation pressure than the outerballoon.

In some embodiments, when the balloons are in the inflated state, theinner balloon has a first balloon shape and the outer balloon has asecond balloon shape that is different from the first balloon shape.

In certain embodiments, the inner balloon is made from a first material,and the outer balloon is made from a second material that is differentfrom the first material.

In various embodiments, the first material can have a first compliance,and the second material can have a second compliance that is greaterthan the first compliance so that the outer balloon expands at a fasterrate than the inner balloon when the balloons are expanded to aninflated state.

In some embodiments, the first material is non-compliant, and the secondmaterial is semi-compliant.

In certain embodiments, the first material is non-compliant, and thesecond material is compliant.

In various embodiments, the first material is semi-compliant, and thesecond material is compliant.

In some embodiments, the energy guide is positioned substantiallydirectly adjacent to an outer surface of the inner balloon.

In certain embodiments, the energy guide is adhered to the outer surfaceof the inner balloon.

In various embodiments, the energy guide is positioned spaced apart fromthe outer surface of the inner balloon.

In some embodiments, the catheter system further includes a guidesupport structure that is mounted on the outer surface of the innerballoon, and the energy guide is positioned on the guide supportstructure so that the energy guide is positioned spaced apart from theouter surface of the inner balloon.

In certain implementations, the heart valve includes a valve wall; andthe balloon assembly is positioned adjacent to the valve wall.

In various implementations, the heart valve includes a plurality ofleaflets; and the balloon assembly is positioned adjacent to at leastone of the plurality of leaflets.

In some embodiments, the catheter system further includes a plasmagenerator that is positioned near a guide distal end of the energyguide, the plasma generator being configured to generate theplasma-induced bubble in the balloon fluid within the interstitial spacebetween the balloons.

In certain embodiments, the guide distal end of the energy guide ispositioned within the interstitial space between the balloonsapproximately at a midpoint of the heart valve.

In some embodiments, the plasma-induced bubble formation impartspressure waves upon the balloon wall of the outer balloon adjacent tothe treatment site.

In certain embodiments, the energy source generates pulses of energythat are guided along the energy guide into the interstitial spacebetween the balloons to generate the plasma-induced bubble formation inthe balloon fluid within the interstitial space between the balloons.

In various embodiments, the energy source is a laser source thatprovides pulses of laser energy.

In some embodiments, the energy guide can include an optical fiber.

In certain embodiments, the energy source is a high voltage energysource that provides pulses of high voltage.

In some embodiments, the energy guide can include an electrode pairincluding spaced apart electrodes that extend into the interstitialspace between the balloons.

In various embodiments, pulses of high voltage from the energy sourceare applied to the electrodes and form an electrical arc across theelectrodes.

In certain embodiments, the catheter system further includes a cathetershaft, and a balloon proximal end of at least one of the balloons can becoupled to the catheter shaft.

In some embodiments, the catheter system further includes (i) a guideshaft that is positioned at least partially within the catheter shaft,the guide shaft defining a guidewire lumen, and (ii) a guidewire that ispositioned to extend through the guidewire lumen, the guidewire beingconfigured to guide movement of the balloon assembly so that the balloonassembly is positioned substantially adjacent to the treatment site.

In various embodiments, the catheter system further includes a pluralityof energy guides that are configured to receive energy from the energysource, and a portion of each of the plurality of energy guides thatreceive the energy from the energy source can be positioned within theinterstitial space between the balloons so that a plasma-induced bubbleis formed in the balloon fluid within the interstitial space.

The present invention is also directed toward a method for treating atreatment site within or adjacent to a heart valve within a body of apatient, the method including the steps of (i) generating energy with anenergy source; (ii) receiving energy from the energy source with anenergy guide; (iii) positioning a balloon assembly substantiallyadjacent to the treatment site, the balloon assembly including an outerballoon and an inner balloon that is positioned substantially within theouter balloon, each of the balloons having a balloon wall that defines aballoon interior, each of the balloons being configured to retain aballoon fluid within the balloon interior, the balloon wall of the innerballoon being positioned spaced apart from the balloon wall of the outerballoon to define an interstitial space therebetween; and (iv)positioning a portion of the energy guide that receives the energy fromthe energy source within the interstitial space between the balloons sothat a plasma-induced bubble is formed in the balloon fluid within theinterstitial space.

The present invention is also directed toward a catheter system fortreating a treatment site within or adjacent to a heart valve within abody of a patient, including an energy source, an energy guide, and aballoon assembly. In various embodiments, the energy source generatesenergy. The energy guide is configured to receive energy from the energysource. The balloon assembly is positionable adjacent to the treatmentsite. The balloon assembly can include an outer balloon and an innerballoon that is positioned substantially within the outer balloon. Theinner balloon can be made from a first material having a firstcompliance, and the outer balloon can be made from a second materialthat is different from the first material. In certain embodiments, thesecond material can have a second compliance that is greater than thefirst compliance. Each of the balloons can have a balloon wall thatdefines a balloon interior. Each of the balloons can be configured toretain a balloon fluid within the balloon interior. The balloon wall ofthe inner balloon can be positioned spaced apart from the balloon wallof the outer balloon to define an interstitial space therebetween. Eachof the balloons can be inflatable with the balloon fluid to expand to aninflated state. In various embodiments, when the balloons are in theinflated state, (i) the inner balloon has an inner balloon diameter,(ii) the outer balloon has an outer balloon diameter that is at leastapproximately 5% greater than the inner balloon diameter, and/or (iii)the inner balloon is inflated to a greater inflation pressure than theouter balloon. In at least some embodiments, a portion of the energyguide can be positioned within the interstitial space between theballoons to generate a plasma-induced bubble in the balloon fluid withinthe interstitial space upon the energy guide receiving energy from theenergy source.

This summary is an overview of some of the teachings of the presentapplication and is not intended to be an exclusive or exhaustivetreatment of the present subject matter. Further details are found inthe detailed description and appended claims. Other aspects will beapparent to persons skilled in the art upon reading and understandingthe following detailed description and viewing the drawings that form apart thereof, each of which is not to be taken in a limiting sense. Thescope herein is defined by the appended claims and their legalequivalents.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of this invention, as well as the invention itself,both as to its structure and its operation, will be best understood fromthe accompanying drawings, taken in conjunction with the accompanyingdescription, in which similar reference characters refer to similarparts, and in which:

FIG. 1 is a schematic cross-sectional view of an embodiment of acatheter system in accordance with various embodiments herein, thecatheter system including a valvular lithoplasty balloon assembly havingfeatures of the present invention;

FIG. 2A is a simplified side view of a portion of a heart valve and aportion of an embodiment of the catheter system including an embodimentof the valvular lithoplasty balloon assembly;

FIG. 2B is a simplified cutaway view of the catheter system includingthe valvular lithoplasty balloon assembly taken on line 2B-2B in FIG.2A;

FIG. 3 is a simplified cutaway view of a portion of another embodimentof the catheter system including another embodiment of the valvularlithoplasty balloon assembly; and

FIG. 4 is a simplified side view of a portion of a fluid flow systemusable within the catheter system.

While embodiments of the present invention are susceptible to variousmodifications and alternative forms, specifics thereof have been shownby way of example and drawings, and are described in detail herein. Itis understood, however, that the scope herein is not limited to theparticular embodiments described. On the contrary, the intention is tocover modifications, equivalents, and alternatives falling within thespirit and scope herein.

DESCRIPTION

Treatment of vascular lesions (also sometimes referred to herein as“treatment sites”) can reduce major adverse events or death in affectedsubjects. As referred to herein, a major adverse event is one that canoccur anywhere within the body due to the presence of a vascular lesion.Major adverse events can include, but are not limited to, major adversecardiac events, major adverse events in the peripheral or centralvasculature, major adverse events in the brain, major adverse events inthe musculature, or major adverse events in any of the internal organs.

As used herein, the terms “treatment site”, “intravascular lesion” and“vascular lesion” are used interchangeably unless otherwise noted. Assuch, the intravascular lesions and/or the vascular lesions aresometimes referred to herein simply as “lesions”.

Those of ordinary skill in the art will realize that the followingdetailed description of the present invention is illustrative only andis not intended to be in any way limiting. Other embodiments of thepresent invention will readily suggest themselves to such skilledpersons having the benefit of this disclosure. Additionally, othermethods of delivering energy to the lesion can be utilized, including,but not limited to electric current induced plasma generation. Referencewill now be made in detail to implementations of the present inventionas illustrated in the accompanying drawings. The same or similarnomenclature and/or reference indicators will be used throughout thedrawings and the following detailed description to refer to the same orlike parts.

In the interest of clarity, not all of the routine features of theimplementations described herein are shown and described. It isappreciated that in the development of any such actual implementation,numerous implementation-specific decisions must be made in order toachieve the developer's specific goals, such as compliance withapplication-related and business-related constraints, and that thesespecific goals will vary from one implementation to another and from onedeveloper to another. Moreover, it is recognized that such a developmenteffort might be complex and time-consuming, but would nevertheless be aroutine undertaking of engineering for those of ordinary skill in theart having the benefit of this disclosure.

The catheter systems disclosed herein can include many different forms.Referring now to FIG. 1, a schematic cross-sectional view is shown of acatheter system 100 in accordance with various embodiments. The cathetersystem 100 is suitable for imparting pressure waves to induce fracturesin one or more treatment sites within or adjacent leaflets within theaortic valve or other appropriate heart valve. In the embodimentillustrated in FIG. 1, the catheter system 100 can include one or moreof a catheter 102, an energy guide bundle 122 including one or moreenergy guides 122A, a source manifold 136, a fluid pump 138, a systemconsole 123 including one or more of an energy source 124, a powersource 125, a system controller 126, and a graphic user interface 127 (a“GUI”), and a handle assembly 128. Additionally, as described herein,the catheter 102 includes a valvular lithoplasty balloon assembly 104(also sometimes referred to herein simply as a “balloon assembly”),including an inner balloon 104A and an outer balloon 104B, that isconfigured to be selectively positioned adjacent to a valve wall 108A(including annulus and commissures) and/or on or between adjacentleaflets 108B within a heart valve 108, e.g., the aortic valve, at atreatment site 106. Alternatively, the catheter system 100 can have morecomponents or fewer components than those specifically illustrated anddescribed in relation to FIG. 1.

The catheter 102 is configured to move to the treatment site 106 withinor adjacent to the heart valve 108 within a body 107 of a patient 109.The treatment site 106 can include one or more vascular lesions 106Asuch as calcified vascular lesions, for example. Additionally, or in thealternative, the treatment site 106 can include vascular lesions 106Asuch as fibrous vascular lesions.

It is appreciated that the illustration of the heart valve 108 in FIG.1, including the valve wall 108A and the leaflets 108B, is merely asimplified representation of the heart valve 108, and is not intended torepresent the actual size and shape of the heart valve 108 and thecomponents thereof. It is also appreciated that FIG. 1 furtherillustrates certain portions of a heart wall of a heart of the patient109 that extend in either direction away from the heart valve 108. It isfurther appreciated that the heart wall of the heart is illustrated as astraight tube in FIG. 1 for purposes of simplicity, and the actual shapeof the heart wall is reality is much more complex than what is actuallyshown in FIG. 1.

The catheter 102 can include a catheter shaft 110, a guide shaft 118,the valvular lithoplasty balloon assembly 104, and a guidewire 112.

The catheter shaft 110 can extend from a proximal portion 114 of thecatheter system 100 to a distal portion 116 of the catheter system 100.The catheter shaft 110 can include a longitudinal axis 144. The guideshaft 118 can be positioned, at least in part, within the catheter shaft110. The guide shaft 118 can define a guidewire lumen which isconfigured to move over the guidewire 112 and/or through which theguidewire 112 extends. The catheter shaft 110 can further include one ormore inflation lumens (not shown) and/or various other lumens forvarious other purposes. For example, in one embodiment, the cathetershaft 110 includes a separate inflation lumen that is configured toprovide a balloon fluid 132 for each of the inner balloon 104A and theouter balloon 104B of the balloon assembly 104. In some embodiments, thecatheter 102 can have a distal end opening 120 and can accommodate andbe tracked over the guidewire 112 as the catheter 102 is moved andpositioned at or near the treatment site 106.

The balloon assembly 104 can be coupled to the catheter shaft 110. Invarious embodiments, the balloon assembly 104 includes the inner balloon104A and the outer balloon 104B, which is positioned to substantially,if not entirely, encircle the inner balloon 104A. Stated in anothermanner, the balloon assembly 104 includes the outer balloon 104B, andthe inner balloon 104A that is positioned at least substantially, if notentirely, within the outer balloon 104B. During use of the cathetersystem 100, the outer balloon 104B can be positioned adjacent to thevalve wall 108A and/or on or between adjacent leaflets 108B within theheart valve 108 at the treatment site 106.

Each balloon 104A, 104B of the balloon assembly 104 can include aballoon proximal end 104P and a balloon distal end 104D. In someembodiments, the balloon proximal end 104P of at least one of theballoons 104A, 104B can be coupled to the catheter shaft 110.Additionally, in certain embodiments, the balloon distal end 104D of atleast one of the balloons 104A, 104B can be coupled to the guide shaft118. For example, in some embodiments, the balloon proximal end 104P ofthe inner balloon 104A is coupled to and/or secured to the cathetershaft 110 and the balloon distal end 104D of the inner balloon 104A iscoupled to and/or secured to the guide shaft 118; and the balloonproximal end 104P of the outer balloon 104B is coupled to and/or securedto the balloon proximal end 104P of the inner balloon 104A and theballoon distal end 104D of the outer balloon 104A is coupled to and/orsecured to the balloon distal end 104D of the inner balloon 104A.Alternatively, in other embodiments, the balloon proximal end 104P ofeach of the inner balloon 104A and the outer balloon 104B is coupled toand/or secured to the catheter shaft 110; and the balloon distal end104D of each of the inner balloon 104A and the outer balloon 104B iscoupled to and/or secured to the guide shaft 118.

It is appreciated that the inner balloon 104A can be coupled to and/orsecured to the catheter shaft 110 and the guide shaft 118 in anysuitable manner. For example, in one non-exclusive embodiment, theballoon proximal end 104P of the inner balloon 104A can be heat-bondedto the catheter shaft 110, and the balloon distal end 104D of the innerballoon 104A can be heat-bonded to the guide shaft 118. Similarly, theouter balloon 104B can be coupled to and/or secured to the cathetershaft 110, the guide shaft 118 and/or the inner balloon 104A in anysuitable manner. For example, in one non-exclusive embodiment, theballoon proximal end 104P of the outer balloon 104B can be heat-bondedto the catheter shaft 110, and the balloon distal end 104D of the outerballoon 104B can be heat-bonded to the guide shaft 118. Alternatively,in another embodiment, the balloon proximal end 104P of the outerballoon 104B can be heat-bonded to the balloon proximal end 104P of theinner balloon 104A, and/or the balloon distal end 104D of the outerballoon 104B can be heat-bonded to the balloon distal end 104D of theinner balloon 104A. Still alternatively, the inner balloon 104A can becoupled to and/or secured to the catheter shaft 110 and the guide shaft118 in another suitable manner, and/or the outer balloon 104B can becoupled to and/or secured to the catheter shaft 110, the guide shaft 118and/or the inner balloon 104A in another suitable manner, such as withadhesives.

Each balloon 104A, 104B includes a balloon wall 130 that defines aballoon interior 146. Each balloon 104A, 104B can be selectivelyinflated with the balloon fluid 132 to expand from a deflated statesuitable for advancing the catheter 102 through a patient's vasculature,to an inflated state (as shown in FIG. 1) suitable for anchoring thecatheter 102 in position relative to the treatment site 106. Inparticular, when the balloons 104A, 104B are in the inflated state, theballoon wall 130 of the outer balloon 104B is configured to bepositioned substantially adjacent to the treatment site 106.

Additionally, as shown in FIG. 1, when the balloons 104A, 104B are inthe inflated state, at least a portion of the balloon wall 130 of theouter balloon 104B is spaced apart from the balloon wall 130 of theinner balloon 104A so as to define an interstitial space 146Atherebetween. It is appreciated that the interstitial space 146A betweenthe inner balloon 104A and the outer balloon 104B when the balloons104A, 104B are in the inflated state can be created in any suitablemanner. For example, in certain non-exclusive embodiments, theinterstitial space 146A between the inner balloon 104A and the outerballoon 104B can be created by one or more of (i) forming the innerballoon 104A and the outer balloon 104B from different materials fromone another, (ii) forming the inner balloon 104A and the outer balloon104B to have different diameters from one another when inflated, and(iii) forming the inner balloon 104A and the outer balloon 104B to havedifferent shapes from one another when inflated.

The balloons 104A, 104B can be formed from any suitable materials. Theballoons 104A, 104B suitable for use in the balloon assembly 104 withinthe catheter system 100 include those that can be passed through thevasculature of a patient when in the deflated state. In variousembodiments, the inner balloon 104A and the outer balloon 104B can beformed from different materials, such as having the outer balloon 104Bmade from a material that is more compliant than the material used forthe inner balloon 104A so that when the two balloons 104A, 104B areinflated the outer balloon 104B can expand at a different, faster ratethan the inner balloon 104A and therefore create a larger interstitialspace 146A between the balloons 104A, 104B. More specifically, incertain embodiments, the outer balloon 104B has an outer ballooncompliance over a working range as the outer balloon 104B is expandedfrom the deflated state to the inflated state, and the inner balloon104A has an inner balloon compliance over a working range as the innerballoon 104A is expanded from the deflated state to the inflated state.In some such embodiments, the outer balloon compliance of the outerballoon 104B can be at least approximately 1%, 2%, 3%, 4%, 5%, 6%, 7%,8%, 9%, 10%, 11%, 12%, 13%, 14%, 15%, 16%, 17%, 18%, 19%, 20%, 25%, 30%,35%, 40%, 45% or 50% greater that the inner balloon compliance of theinner balloon 104A. Alternatively, the difference between the outerballoon compliance of the outer balloon 104B and the inner ballooncompliance of the inner balloon 104A can be different than the valuesnoted above.

In some embodiments, the balloons 104A, 104B are made from silicone. Inother embodiments, the balloons 104A, 104B can be made from materialssuch as polydimethylsiloxane (PDMS), polyurethane, polymers such asPEBAX™ material, nylon, polyethylene terephthalate (PET), or any othersuitable material. Additionally, in certain embodiments, the balloons104A, 104B can be impermeable, such that no apertures are intentionallyformed into and/or through the balloon wall 130 to allow the balloonfluid 132 and/or any suitable therapeutic agent to pass therethrough.

In certain embodiments, the outer balloon 104B can be formed fromcompliant materials such as urethanes, lower durometer PEBAX™, andnylons, or semi-compliant materials such as PEBAX™, and nylon blendswith urethanes and silicone; and the inner balloon 104A can be formedfrom semi-compliant materials such as PEBAX™, and nylon blends withurethanes and silicone, or non-compliant materials such as PET. Morespecifically, in one non-exclusive such embodiment, the outer balloon104B can be formed from a compliant material and the inner balloon 104Acan be formed from a semi-compliant material. In another non-exclusivesuch embodiment, the outer balloon 104B can be formed from a compliantmaterial and the inner balloon 104A can be formed from a non-compliantmaterial. In still another non-exclusive such embodiment, the outerballoon 104B can be formed from a semi-compliant material and the innerballoon 104A can be formed from a non-compliant material. As noted, thedifferent compliances between the materials for the outer balloon 104Band the inner balloon 104A are configured such that the balloons 104A,104B expand at different rates to help create the interstitial space146A between the balloons 104A, 104B when the balloons 104A, 104B are inthe inflated state.

As utilized herein, a non-compliant or semi-compliant balloon is definedas one that inflates to a predetermined shape, and changes to this shapeare relatively insensitive to the internal inflation pressure. Forexample, in some non-exclusive applications, a non-compliant balloon isa balloon with less than approximately 6% compliance over a workingrange, and a semi-compliant balloon is a balloon with betweenapproximately 6% to 12% compliance over the working range. Additionally,in such applications, a compliant balloon is a balloon with greater than12% compliance over the working range.

The balloons 104A, 104B can have any suitable diameter (in the inflatedstate). In various embodiments, the balloons 104A, 104B can have adiameter (in the inflated state) ranging from less than one millimeter(mm) up to 30 mm. In some embodiments, the balloons 104A, 104B can havea diameter (in the inflated state) ranging from at least 1.5 mm up to 14mm. In some embodiments, the balloons 104A, 104B can have a diameter (inthe inflated state) ranging from at least two mm up to five mm.

In various embodiments, the outer balloon 104B and the inner balloon104A are configured to have different diameters from one another whenthe balloons 104A, 104B are in the inflated state. In certainnon-exclusive alternative embodiments, the inner balloon 104A can havean inner balloon diameter when in the inflated state, and the outerballoon 104B can have an outer balloon diameter when in the inflatedstate that is at least approximately 1%, 2%, 3%, 5%, 7%, 10%, 12%, 15%,17%, 20%, 22%, 25%, 27%, 30%, 32%, 35%, 37%, 40%, 42%, 45%, 47% or 50%greater than the inner balloon diameter of the inner balloon 104A.Alternatively, the difference between the outer balloon diameter of theouter balloon 104B and the inner balloon diameter of the inner balloon104A can be different than the values noted above. As noted, thedifference between the outer balloon diameter and the inner balloondiameter, with the outer balloon diameter being greater than the innerballoon diameter, is configured to help create the interstitial space146A between the balloons 104A, 104B when the balloons 104A, 104B are inthe inflated state.

In some embodiments, the balloons 104A, 104B can have a length rangingfrom at least three mm to 300 mm. More particularly, in someembodiments, the balloons 104A, 104B can have a length ranging from atleast eight mm to 200 mm. It is appreciated that balloons 104A, 104Bhaving a relatively longer length can be positioned adjacent to largertreatment sites 106, and, thus, may be usable for imparting pressurewaves onto and inducing fractures in larger vascular lesions 106A ormultiple vascular lesions 106A at precise locations within the treatmentsite 106. It is further appreciated that longer balloons 104A, 104B canalso be positioned adjacent to multiple treatment sites 106 at any onegiven time.

The balloons 104A, 104B can be inflated to inflation pressures ofbetween approximately one atmosphere (atm) and 70 atm. In someembodiments, the balloons 104A, 104B can be inflated to inflationpressures of from at least 20 atm to 60 atm. In other embodiments, theballoons 104A, 104B can be inflated to inflation pressures of from atleast six atm to 20 atm. In still other embodiments, the balloons 104A,104B can be inflated to inflation pressures of from at least three atmto 20 atm. In yet other embodiments, the balloons 104A, 104B can beinflated to inflation pressures of from at least two atm to ten atm.

In certain embodiments, the inner balloon 104A and the outer balloon104B can be inflated to different inflation pressures. In suchembodiments, the inner balloon 104A can be pressurized at a higherinflation pressure than the outer balloon 104B to improve the energytransfer by better directing the energy into the vascular lesions 106Aat the treatment site 106. More specifically, the improved energytransfer is achieved by keeping the balloon wall 130 of the innerballoon 104A immovable at high pressure so that the energy is notabsorbed by movement of the balloon wall 130 of the inner balloon 104A,but rather is directed in a generally outward direction to the balloonwall 130 of the outer balloon 104B positioned at the treatment site 106.In certain non-exclusive embodiments, the inner balloon 104A can beinflated to an inflation pressure that is between approximately 0.1 atmand 8 atmospheres greater than the inflation pressure for the outerballoon 104B. Alternatively, the difference in inflation pressure in theinner balloon 104A and the outer balloon 104B can be different than thevalues noted above.

The balloons 104A, 104B can have various shapes, including, but not tobe limited to, a conical shape, a square shape, a rectangular shape, aspherical shape, a conical/square shape, a conical/spherical shape, anextended spherical shape, an oval shape, a tapered shape, a bone shape,an hourglass shape, a stepped diameter shape, an offset or asymmetricalshape, or a conical offset shape. In some embodiments, the balloons104A, 104B can include a drug eluting coating, or a drug eluting stentstructure. The drug eluting coating or drug eluting stent can includeone or more therapeutic agents including anti-inflammatory agents,anti-neoplastic agents, anti-angiogenic agents, and the like. In otherembodiments, the balloons 104A, 104B can include any suitable type ofstent structure. Additionally or in the alternative, in variousapplications, use of a stent is inappropriate and the valvuloplastyprocedure can be followed by the positioning of an artificialreplacement valve into the valve area.

In various embodiments, the shape of the inner balloon 104A can bedifferent than the shape of the outer balloon 104B to help create theinterstitial space 146A between the balloons 104A, 104B when theballoons 104A, 104B are in the inflated state. More particularly, insuch embodiments, the inner balloon 104A can have a first shape and theouter balloon 104B can have a second shape that is different than thefirst shape to help create the interstitial space 146A and to moreeffectively optimize energy delivery.

The balloon fluid 132 can be a liquid or a gas. Some examples of theballoon fluid 132 suitable for use can include, but are not limited toone or more of water, saline, contrast medium, fluorocarbons,perfluorocarbons, gases, such as carbon dioxide, or any other suitableballoon fluid 132. In some embodiments, the balloon fluid 132 can beused as a base inflation fluid. In some embodiments, the balloon fluid132 can include a mixture of saline to contrast medium in a volume ratioof approximately 50:50. In other embodiments, the balloon fluid 132 caninclude a mixture of saline to contrast medium in a volume ratio ofapproximately 25:75. In still other embodiments, the balloon fluid 132can include a mixture of saline to contrast medium in a volume ratio ofapproximately 75:25. However, it is understood that any suitable ratioof saline to contrast medium can be used. The balloon fluid 132 can betailored on the basis of composition, viscosity, and the like so thatthe rate of travel of the pressure waves are appropriately manipulated.In certain embodiments, the balloon fluids 132 suitable for use arebiocompatible. A volume of balloon fluid 132 can be tailored by thechosen energy source 124 and the type of balloon fluid 132 used.

In some embodiments, the contrast agents used in the contrast media caninclude, but are not to be limited to, iodine-based contrast agents,such as ionic or non-ionic iodine-based contrast agents. Somenon-limiting examples of ionic iodine-based contrast agents includediatrizoate, metrizoate, iothalamate, and ioxaglate. Some non-limitingexamples of non-ionic iodine-based contrast agents include iopamidol,iohexol, ioxilan, iopromide, iodixanol, and ioversol. In otherembodiments, non-iodine based contrast agents can be used. Suitablenon-iodine containing contrast agents can include gadolinium (III)-basedcontrast agents. Suitable fluorocarbon and perfluorocarbon agents caninclude, but are not to be limited to, agents such as theperfluorocarbon dodecafluoropentane (DDFP, C5F12).

The balloon fluids 132 can include those that include absorptive agentsthat can selectively absorb light in the ultraviolet region (e.g., atleast ten nanometers (nm) to 400 nm), the visible region (e.g., at least400 nm to 780 nm), or the near-infrared region (e.g., at least 780 nm to2.5 μm) of the electromagnetic spectrum. Suitable absorptive agents caninclude those with absorption maxima along the spectrum from at leastten nm to 2.5 μm. Alternatively, the balloon fluids 132 can includethose that include absorptive agents that can selectively absorb lightin the mid-infrared region (e.g., at least 2.5 μm to 15 μm), or thefar-infrared region (e.g., at least 15 μm to one mm) of theelectromagnetic spectrum. In various embodiments, the absorptive agentcan be those that have an absorption maximum matched with the emissionmaximum of the laser used in the catheter system 100. By way ofnon-limiting examples, various lasers usable in the catheter system 100can include neodymium:yttrium-aluminum-garnet (Nd:YAG−emissionmaximum=1064 nm) lasers, holmium:YAG (Ho:YAG−emission maximum=2.1 μm)lasers, or erbium:YAG (Er:YAG−emission maximum=2.94 μm) lasers. In someembodiments, the absorptive agents can be water soluble. In otherembodiments, the absorptive agents are not water soluble. In someembodiments, the absorptive agents used in the balloon fluids 132 can betailored to match the peak emission of the energy source 124. Variousenergy sources 124 having emission wavelengths of at least tennanometers to one millimeter are discussed elsewhere herein.

The catheter shaft 110 of the catheter 102 can be coupled to the one ormore energy guides 122A of the energy guide bundle 122 that are inoptical communication with the energy source 124. Each energy guide 122Acan be disposed along the catheter shaft 110 and within the interstitialspace 146A between the inner balloon 104A and the outer balloon 104B. Insome embodiments, each energy guide 122A can be adhered and/or attachedto an outer surface 104S of the inner balloon 104A. Alternatively, inother embodiments, one or more of the energy guides 122A can be fixedonto a separate support structure (not shown in FIG. 1) such as anitinol scaffold. In some embodiments, each energy guide 122A can be anoptical fiber and the energy source 124 can be a laser. The energysource 124 can be in optical communication with the energy guides 122Aat the proximal portion 114 of the catheter system 100.

In some embodiments, the catheter shaft 110 can be coupled to multipleenergy guides 122A such as a first energy guide, a second energy guide,a third energy guide, a fourth energy guide, etc., which can be disposedat any suitable positions about the guide shaft 118 and/or the cathetershaft 110. For example, in certain non-exclusive embodiments, two energyguides 122A can be spaced apart by approximately 180 degrees about thecircumference of the guide shaft 118 and/or the catheter shaft 110;three energy guides 122A can be spaced apart by approximately 120degrees about the circumference of the guide shaft 118 and/or thecatheter shaft 110; four energy guides 122A can be spaced apart byapproximately 90 degrees about the circumference of the guide shaft 118and/or the catheter shaft 110; five energy guides 122A can be spacedapart by approximately 72 degrees about the circumference of the guideshaft 118 and/or the catheter shaft 110; or six energy guides 122A canbe spaced apart by approximately 60 degrees about the circumference ofthe guide shaft 118 and/or the catheter shaft 110. Still alternatively,multiple energy guides 122A need not be uniformly spaced apart from oneanother about the circumference of the guide shaft 118 and/or thecatheter shaft 110. More particularly, it is further appreciated thatthe energy guides 122A can be disposed uniformly or non-uniformly aboutthe guide shaft 118 and/or the catheter shaft 110 to achieve the desiredeffect in the desired locations.

The catheter system 100 and/or the energy guide bundle 122 can includeany number of energy guides 122A in optical communication with theenergy source 124 at the proximal portion 114, and with the balloonfluid 132 within the interstitial space 146A between the balloons 104A,104B at the distal portion 116. For example, in some embodiments, thecatheter system 100 and/or the energy guide bundle 122 can include fromone energy guide 122A to greater than 30 energy guides 122A.

The energy guides 122A can have any suitable design for purposes ofgenerating plasma-induced bubbles 134 and/or pressure waves in theballoon fluid 132 within the interstitial space 146A between theballoons 104A, 104B. Thus, the general description of the energy guides122A as light guides is not intended to be limiting in any manner,except for as set forth in the claims appended hereto. Moreparticularly, although the catheter systems 100 are often described withthe energy source 124 as a light source and the one or more energyguides 122A as light guides, the catheter system 100 can alternativelyinclude any suitable energy source 124 and energy guides 122A forpurposes of generating the desired plasma-induced bubble(s) 134 in theballoon fluid 132 within the interstitial space 146A between theballoons 104A, 104B. For example, in one non-exclusive alternativeembodiment, the energy source 124 can be configured to provide highvoltage pulses, and each energy guide 122A can include an electrode pairincluding spaced apart electrodes that extend into the interstitialspace 146A between the balloons 104A, 104B. In such embodiment, eachpulse of high voltage is applied to the electrodes and forms anelectrical arc across the electrodes, which, in turn, generates theplasma 134 and forms the pressure waves within the balloon fluid 132that are utilized to provide the fracture force onto the vascularlesions 106A at the treatment site 106. Still alternatively, the energysource 124 and/or the energy guides 122A can have another suitabledesign and/or configuration.

In certain embodiments, the energy guides 122A can include an opticalfiber or flexible light pipe. The energy guides 122A can be thin andflexible and can allow light signals to be sent with very little loss ofstrength. The energy guides 122A can include a core surrounded by acladding about its circumference. In some embodiments, the core can be acylindrical core or a partially cylindrical core. The core and claddingof the energy guides 122A can be formed from one or more materials,including but not limited to one or more types of glass, silica, or oneor more polymers. The energy guides 122A may also include a protectivecoating, such as a polymer. It is appreciated that the index ofrefraction of the core will be greater than the index of refraction ofthe cladding.

Each energy guide 122A can guide energy along its length from a guideproximal end 122P to a guide distal end 122D having at least one opticalwindow (not shown) that is positioned within the interstitial space 146Abetween the balloons 104A, 104B. In one non-exclusive embodiment, theguide distal end 122D of each energy guide 122A can be positioned withinthe interstitial space 146A so as to be positioned approximately at amidpoint of the heart valve 108. With such design, upon expansion of theballoons 104A, 104B to the inflated state, the pressure waves generatedin the balloon fluid 132 within the interstitial space 146A between theballoons 104A, 104B can put pressure on any desired portion of the heartvalve 108, e.g., the valve wall 108A, the commissures, the annulusand/or the leaflets 108B. Alternatively, the energy guides 122A can haveanother suitable design and/or the energy from the energy source 124 canbe guided into the interstitial space 146A between the balloons 104A,104B by another suitable method.

The energy guides 122A can assume many configurations about and/orrelative to the catheter shaft 110 of the catheter 102. In someembodiments, the energy guides 122A can run parallel to the longitudinalaxis 144 of the catheter shaft 110. In some embodiments, the energyguides 122A can be physically coupled to the catheter shaft 110. Inother embodiments, the energy guides 122A can be disposed along a lengthof an outer diameter of the catheter shaft 110. In yet otherembodiments, the energy guides 122A can be disposed within one or moreenergy guide lumens within the catheter shaft 110.

As noted, in some embodiments, each energy guide 122A can be adheredand/or attached to the outer surface 104S of the inner balloon 104A.With such design, the guide distal end 122D of each energy guide 122Acan be positioned substantially directly adjacent to the outer surface104S of the inner balloon 104A. Alternatively, in other embodiments, oneor more of the energy guides 122A can be fixed onto a separate supportstructure such as a nitinol scaffold. With such alternative design, theguide distal end 122D of each of the energy guides 122A can bepositioned spaced apart from the outer surface 104S of the inner balloon104A.

The energy guides 122A can also be disposed at any suitable positionsabout the circumference of the guide shaft 118 and/or the catheter shaft110, and the guide distal end 122D of each of the energy guides 122A canbe disposed at any suitable longitudinal position relative to the lengthof the balloons 104A, 104B and/or relative to the length of the guideshaft 118.

In certain embodiments, the energy guides 122A can include one or morephotoacoustic transducers 154, where each photoacoustic transducer 154can be in optical communication with the energy guide 122A within whichit is disposed. In some embodiments, the photoacoustic transducers 154can be in optical communication with the guide distal end 122D of theenergy guide 122A. Additionally, in such embodiments, the photoacoustictransducers 154 can have a shape that corresponds with and/or conformsto the guide distal end 122D of the energy guide 122A.

The photoacoustic transducer 154 is configured to convert light energyinto an acoustic wave at or near the guide distal end 122D of the energyguide 122A. The direction of the acoustic wave can be tailored bychanging an angle of the guide distal end 122D of the energy guide 122A.

In certain embodiments, the photoacoustic transducers 154 disposed atthe guide distal end 122D of the energy guide 122A can assume the sameshape as the guide distal end 122D of the energy guide 122A. Forexample, in certain non-exclusive embodiments, the photoacoustictransducer 154 and/or the guide distal end 122D can have a conicalshape, a convex shape, a concave shape, a bulbous shape, a square shape,a stepped shape, a half-circle shape, an ovoid shape, and the like. Theenergy guide 122A can further include additional photoacoustictransducers 154 disposed along one or more side surfaces of the lengthof the energy guide 122A.

In some embodiments, the energy guides 122A can further include one ormore diverting features or “diverters” (not shown in FIG. 1) within theenergy guide 122A that are configured to direct energy to exit theenergy guide 122A toward a side surface which can be located at or nearthe guide distal end 122D of the energy guide 122A, and toward theballoon wall 130 of the outer balloon 104B. A diverting feature caninclude any feature of the system that diverts energy from the energyguide 122A away from its axial path toward a side surface of the energyguide 122A. Additionally, the energy guides 122A can each include one ormore optical windows disposed along the longitudinal or circumferentialsurfaces of each energy guide 122A and in optical communication with adiverting feature. Stated in another manner, the diverting features canbe configured to direct energy in the energy guide 122A toward a sidesurface that is at or near the guide distal end 122D, where the sidesurface is in optical communication with an optical window. The opticalwindows can include a portion of the energy guide 122A that allowsenergy to exit the energy guide 122A from within the energy guide 122A,such as a portion of the energy guide 122A lacking a cladding materialon or about the energy guide 122A.

Examples of the diverting features suitable for use include a reflectingelement, a refracting element, and a fiber diffuser. The divertingfeatures suitable for focusing energy away from the tip of the energyguides 122A can include, but are not to be limited to, those having aconvex surface, a gradient-index (GRIN) lens, and a mirror focus lens.Upon contact with the diverting feature, the energy is diverted withinthe energy guide 122A to one or more of a plasma generator 133 and thephotoacoustic transducer 154 that is in optical communication with aside surface of the energy guide 122A. The photoacoustic transducer 154then converts light energy into an acoustic wave that extends away fromthe side surface of the energy guide 122A.

The source manifold 136 can be positioned at or near the proximalportion 114 of the catheter system 100. The source manifold 136 caninclude one or more proximal end openings that can receive the one ormore energy guides 122A of the energy guide bundle 122, the guidewire112, and/or an inflation conduit 140 that is coupled in fluidcommunication with the fluid pump 138. The catheter system 100 can alsoinclude the fluid pump 138 that is configured to inflate each balloon104A, 104B of the balloon assembly 104 with the balloon fluid 132, i.e.via the inflation conduit 140, as needed.

As noted above, in the embodiment illustrated in FIG. 1, the systemconsole 123 includes one or more of the energy source 124, the powersource 125, the system controller 126, and the GUI 127. Alternatively,the system console 123 can include more components or fewer componentsthan those specifically illustrated in FIG. 1. For example, in certainnon-exclusive alternative embodiments, the system console 123 can bedesigned without the GUI 127. Still alternatively, one or more of theenergy source 124, the power source 125, the system controller 126, andthe GUI 127 can be provided within the catheter system 100 without thespecific need for the system console 123.

As shown, the system console 123, and the components included therewith,is operatively coupled to the catheter 102, the energy guide bundle 122,and the remainder of the catheter system 100. For example, in someembodiments, as illustrated in FIG. 1, the system console 123 caninclude a console connection aperture 148 (also sometimes referred togenerally as a “socket”) by which the energy guide bundle 122 ismechanically coupled to the system console 123. In such embodiments, theenergy guide bundle 122 can include a guide coupling housing 150 (alsosometimes referred to generally as a “ferrule”) that houses a portion,e.g., the guide proximal end 122P, of each of the energy guides 122A.The guide coupling housing 150 is configured to fit and be selectivelyretained within the console connection aperture 148 to provide themechanical coupling between the energy guide bundle 122 and the systemconsole 123.

The energy guide bundle 122 can also include a guide bundler 152 (or“shell”) that brings each of the individual energy guides 122A closertogether so that the energy guides 122A and/or the energy guide bundle122 can be in a more compact form as it extends with the catheter 102into the heart valve 108 during use of the catheter system 100.

The energy source 124 can be selectively and/or alternatively coupled inoptical communication with each of the energy guides 122A, i.e. to theguide proximal end 122P of each of the energy guides 122A, in the energyguide bundle 122. In particular, the energy source 124 is configured togenerate energy in the form of a source beam 124A, such as a pulsedsource beam, that can be selectively and/or alternatively directed toand received by each of the energy guides 122A in the energy guidebundle 122 as an individual guide beam 124B. Alternatively, the cathetersystem 100 can include more than one energy source 124. For example, inone non-exclusive alternative embodiment, the catheter system 100 caninclude a separate energy source 124 for each of the energy guides 122Ain the energy guide bundle 122.

The energy source 124 can have any suitable design. In certainembodiments, the energy source 124 can be configured to providesub-millisecond pulses of energy from the energy source 124 that arefocused onto a small spot in order to couple it into the guide proximalend 122P of the energy guide 122A. Such pulses of energy are thendirected and/or guided along the energy guides 122A to a location withinthe interstitial space 146A between the balloons 104A, 104B, therebyinducing the formation of plasma-induced bubble(s) (134) in the balloonfluid 132 within the interstitial space 146A between the balloons 104A,104B, e.g., via the plasma generator 133 that can be located at or nearthe guide distal end 122D of the energy guide 122A. In particular, theenergy emitted at the guide distal end 122D of the energy guide 122Aenergizes the plasma generator 133 to form the plasma-induced bubble 134in the balloon fluid 132 within the interstitial space 146A between theballoons 104A, 104B. Formation of the plasma-induced bubble(s) 134imparts pressure waves upon the treatment site 106. One exemplaryplasma-induced bubble 134 is illustrated in FIG. 1.

In various non-exclusive alternative embodiments, the sub-millisecondpulses of energy from the energy source 124 can be delivered to thetreatment site 106 at a frequency of between approximately one hertz(Hz) and 5000 Hz, between approximately 30 Hz and 1000 Hz, betweenapproximately ten Hz and 100 Hz, or between approximately one Hz and 30Hz. Alternatively, the sub-millisecond pulses of energy can be deliveredto the treatment site 106 at a frequency that can be greater than 5000Hz or less than one Hz, or any other suitable range of frequencies.

It is appreciated that although the energy source 124 is typicallyutilized to provide pulses of energy, the energy source 124 can still bedescribed as providing a single source beam 124A, i.e. a single pulsedsource beam.

The energy sources 124 suitable for use can include various types oflight sources including lasers and lamps. Alternatively, the energysources 124 can include any suitable type of energy source.

Suitable lasers can include short pulse lasers on the sub-millisecondtimescale. In some embodiments, the energy source 124 can include laserson the nanosecond (ns) timescale. The lasers can also include shortpulse lasers on the picosecond (ps), femtosecond (fs), and microsecond(us) timescales. It is appreciated that there are many combinations oflaser wavelengths, pulse widths and energy levels that can be employedto generate plasma-induced bubble(s) 134 in the balloon fluid 132 of thecatheter 102. In various non-exclusive alternative embodiments, thepulse widths can include those falling within a range including from atleast ten ns to 3000 ns, at least 20 ns to 100 ns, or at least one ns to500 ns. Alternatively, any other suitable pulse width range can be used.

Exemplary nanosecond lasers can include those within the UV to IRspectrum, spanning wavelengths of about ten nanometers (nm) to onemillimeter (mm). In some embodiments, the energy sources 124 suitablefor use in the catheter systems 100 can include those capable ofproducing light at wavelengths of from at least 750 nm to 2000 nm. Inother embodiments, the energy sources 124 can include those capable ofproducing light at wavelengths of from at least 700 nm to 3000 nm. Instill other embodiments, the energy sources 124 can include thosecapable of producing light at wavelengths of from at least 100 nm to tenmicrometers (μm). Nanosecond lasers can include those having repetitionrates of up to 200 kHz.

In some embodiments, the laser can include a Q-switchedthulium:yttrium-aluminum-garnet (Tm:YAG) laser. In other embodiments,the laser can include a neodymium:yttrium-aluminum-garnet (Nd:YAG)laser, holmium:yttrium-aluminum-garnet (Ho:YAG) laser,erbium:yttrium-aluminum-garnet (Er:YAG) laser, excimer laser,helium-neon laser, carbon dioxide laser, as well as doped, pulsed, fiberlasers.

The catheter system 100 can generate pressure waves having maximumpressures in the range of at least one megapascal (MPa) to 100 MPa. Themaximum pressure generated by a particular catheter system 100 willdepend on the energy source 124, the absorbing material, the bubbleexpansion, the propagation medium, the balloon material, and otherfactors. In various non-exclusive alternative embodiments, the cathetersystems 100 can generate pressure waves having maximum pressures in therange of at least approximately two MPa to 50 MPa, at leastapproximately two MPa to 30 MPa, or at least approximately 15 MPa to 25MPa.

The pressure waves can be imparted upon the treatment site 106 from adistance within a range from at least approximately 0.1 millimeters (mm)to greater than approximately 25 mm extending radially from the energyguides 122A when the catheter 102 is placed at the treatment site 106.In various non-exclusive alternative embodiments, the pressure waves canbe imparted upon the treatment site 106 from a distance within a rangefrom at least approximately ten mm to 20 mm, at least approximately onemm to ten mm, at least approximately 1.5 mm to four mm, or at leastapproximately 0.1 mm to ten mm extending radially from the energy guides122A when the catheter 102 is placed at the treatment site 106. In otherembodiments, the pressure waves can be imparted upon the treatment site106 from another suitable distance that is different than the foregoingranges. In some embodiments, the pressure waves can be imparted upon thetreatment site 106 within a range of at least approximately two MPa to30 MPa at a distance from at least approximately 0.1 mm to ten mm. Insome embodiments, the pressure waves can be imparted upon the treatmentsite 106 from a range of at least approximately two MPa to 25 MPa at adistance from at least approximately 0.1 mm to ten mm. Stillalternatively, other suitable pressure ranges and distances can be used.

The power source 125 is electrically coupled to and is configured toprovide necessary power to each of the energy source 124, the systemcontroller 126, the GUI 127, and the handle assembly 128. The powersource 125 can have any suitable design for such purposes.

The system controller 126 is electrically coupled to and receives powerfrom the power source 125. Additionally, the system controller 126 iscoupled to and is configured to control operation of each of the energysource 124 and the GUI 127. The system controller 126 can include one ormore processors or circuits for purposes of controlling the operation ofat least the energy source 124 and the GUI 127. For example, the systemcontroller 126 can control the energy source 124 for generating pulsesof energy as desired and/or at any desired firing rate. Additionally,the system controller 126 can operate to effectively and efficientlyprovide the desired fracture forces adjacent to and/or on or betweenadjacent leaflets 108B within the heart valve 108 at the treatment site106.

The system controller 126 can also be configured to control operation ofother components of the catheter system 100 such as the positioning ofthe catheter 102 and/or the balloon assembly 104 adjacent to thetreatment site 106, the inflation of each balloon 104A, 104B with theballoon fluid 132, etc. Further, or in the alternative, the cathetersystem 100 can include one or more additional controllers that can bepositioned in any suitable manner for purposes of controlling thevarious operations of the catheter system 100. For example, in certainembodiments, an additional controller and/or a portion of the systemcontroller 126 can be positioned and/or incorporated within the handleassembly 128.

The GUI 127 is accessible by the user or operator of the catheter system100. Additionally, the GUI 127 is electrically connected to the systemcontroller 126. With such design, the GUI 127 can be used by the user oroperator to ensure that the catheter system 100 is effectively utilizedto impart pressure onto and induce fractures into the vascular lesions106A at the treatment site 106. The GUI 127 can provide the user oroperator with information that can be used before, during and after useof the catheter system 100. In one embodiment, the GUI 127 can providestatic visual data and/or information to the user or operator. Inaddition, or in the alternative, the GUI 127 can provide dynamic visualdata and/or information to the user or operator, such as video data orany other data that changes over time during use of the catheter system100. In various embodiments, the GUI 127 can include one or more colors,different sizes, varying brightness, etc., that may act as alerts to theuser or operator. Additionally, or in the alternative, the GUI 127 canprovide audio data or information to the user or operator. The specificsof the GUI 127 can vary depending upon the design requirements of thecatheter system 100, or the specific needs, specifications and/ordesires of the user or operator.

As shown in FIG. 1, the handle assembly 128 can be positioned at or nearthe proximal portion 114 of the catheter system 100, and/or near thesource manifold 136. In this embodiment, the handle assembly 128 iscoupled to the balloon assembly 104 and is positioned spaced apart fromthe balloon assembly 104. Alternatively, the handle assembly 128 can bepositioned at another suitable location.

The handle assembly 128 is handled and used by the user or operator tooperate, position and control the catheter 102. The design and specificfeatures of the handle assembly 128 can vary to suit the designrequirements of the catheter system 100. In the embodiment illustratedin FIG. 1, the handle assembly 128 is separate from, but in electricaland/or fluid communication with one or more of the system controller126, the energy source 124, the fluid pump 138, and the GUI 127. In someembodiments, the handle assembly 128 can integrate and/or include atleast a portion of the system controller 126 within an interior of thehandle assembly 128. For example, as shown, in certain such embodiments,the handle assembly 128 can include circuitry 156 that can form at leasta portion of the system controller 126. In one embodiment, the circuitry156 can include a printed circuit board having one or more integratedcircuits, or any other suitable circuitry. In an alternative embodiment,the circuitry 156 can be omitted, or can be included within the systemcontroller 126, which in various embodiments can be positioned outsideof the handle assembly 128, e.g., within the system console 123. It isunderstood that the handle assembly 128 can include fewer or additionalcomponents than those specifically illustrated and described herein.

Descriptions of various embodiments and implementations of the balloonassembly 104, and usages thereof, are described in detail herein below.However, it is further appreciated that alternative embodiments andimplementations may also be employed that would be apparent to thoseskilled in the relevant art based on the teachings provided herein.Thus, the scope of the present embodiments and implementations is notintended to be limited to just those specifically described herein,except as recited in the claims appended hereto.

FIG. 2A is a simplified side view of a portion of the heart valve 108,including the valve wall 108A and the leaflets 108B, and a portion of anembodiment of the catheter system 200 including an embodiment of thevalvular lithoplasty balloon assembly 204. The balloon assembly 204 isagain configured to be selectively positioned adjacent to the valve wall108A and/or between adjacent leaflets 108B within the heart valve 108 ata treatment site 106 including vascular lesions 106A within the body 107and the patient 109.

Similar to the previous embodiments, the catheter system 200 includes acatheter 202 including a catheter shaft 210, a guide shaft 218, and aguidewire 212, such as described above, and the balloon assembly 204.Additionally, the catheter system 200 will typically include variousother components such as illustrated and described in relation toFIG. 1. However, such additional components are not shown in FIG. 2A forpurposes of clarity.

As shown in the embodiment illustrated in FIG. 2A, the balloon assembly204 includes an inner balloon 204A and an outer balloon 204B, which ispositioned to substantially, if not entirely, encircle the inner balloon204A. Stated in another manner, the balloon assembly 204 includes theouter balloon 204B, and the inner balloon 204A that is positioned atleast substantially, if not entirely, within the outer balloon 204B.During use of the catheter system 200, the outer balloon 204B can bepositioned adjacent to the valve wall 108A and/or on or between adjacentleaflets 108B within the heart valve 108 at the treatment site 106.

Each balloon 204A, 204B can include a balloon proximal end 204P and aballoon distal end 204D. As illustrated, in certain implementations, theballoon proximal end 204P of at least one of the balloons 204A, 204B canbe coupled to the catheter shaft 210, and the balloon distal end 204D ofat least one of the balloons 204A, 204B can be coupled to the guideshaft 218. For example, in some such implementations, the balloonproximal end 204P of the inner balloon 204A is coupled to and/or securedto the catheter shaft 210 and the balloon distal end 204D of the innerballoon 204A is coupled to and/or secured to the guide shaft 218. Insuch implementations, the balloon proximal end 204P of the outer balloon204B can also be coupled to and/or secured to the catheter shaft 210,and/or the balloon proximal end 204P of the outer balloon 204B can becoupled to and/or secured to the balloon proximal end 204P of the innerballoon 204A. Additionally, in such implementations, the balloon distalend 204D of the outer balloon 204B can also be coupled to and/or securedto the guide shaft 218, and/or the balloon distal end 204D of the outerballoon 204A can be coupled to and/or secured to the balloon distal end204D of the inner balloon 204A.

FIG. 2A further illustrates that the catheter system 200 includes one ormore energy guides 222A (three are visible in FIG. 2A) that extend intothe interstitial space 246A between the inner balloon 204A and the outerballoon 204B that is created when the balloons 204A, 204B are in theinflated state (as shown in FIG. 2A).

FIG. 2B is a simplified cutaway view of the heart valve 108 and thevalvular lithoplasty balloon assembly 204 taken on line 2B-2B in FIG.2A. It is appreciated that the Figures herein, including FIG. 2B, arenot necessarily drawn to scale, but rather are drawn to more clearlyillustrate the relative positioning of the components of the cathetersystem 200.

As shown, the balloon assembly 204 can be positioned within the heartvalve 108, and with the outer balloon 204B of the balloon assembly 204being positioned adjacent to the valve wall 108A and/or between adjacentleaflets 108B (illustrated in FIG. 2A) within the heart valve 108. Theballoon assembly 204 is also illustrated as being positioned about theguide shaft 218, which provides the conduit through which the guidewire212 extends, in this non-exclusive implementation.

Additionally, each balloon 204A, 204B can include a balloon wall 230that defines a balloon interior 246, and that is configured to receivethe balloon fluid 232 (illustrated in FIG. 2A) within the ballooninterior 246 of each balloon 204A, 204B and/or within the interstitialspace 246A between the balloons 204A, 204B. Each balloon 204A, 204B canthus be selectively inflated with the balloon fluid 232 to expand fromthe deflated state to the inflated state (as shown in FIG. 2B).

Also illustrated in FIG. 2B are the one or more energy guides 222A. Aportion of each energy guide 222A, i.e. the guide distal end 222D, canbe positioned in the balloon fluid 232 within the balloon interior 246of the outer balloon 204B and/or within the interstitial space 246Abetween the balloons 204A, 204B. In this embodiment, the catheter system200 includes four energy guides 222A, with the guide distal end 222D ofeach of the four energy guides 222A positioned in the balloon fluid 232within the balloon interior 246 of the outer balloon 204B and/or withinthe interstitial space 246A between the balloons 204A, 204B. In onenon-exclusive embodiment, the guide distal end 222D of the four energyguides 222A can be substantially uniformly spaced apart from one anotherby approximately 90 degrees about the inner balloon 204A. Alternatively,the catheter system 200 can include greater than four energy guides 222Aor fewer than four energy guides 222A provided that the guide distal end222D of at least one energy guide 222A is positioned within the ballooninterior 246 of the outer balloon 204B and/or within the interstitialspace 246A between the balloons 204A, 204B.

In this embodiment, the interstitial space 246A between the balloons204A, 204B is created, at least in part, by a diameter of each balloon204A, 204B being different from one another when the balloons 204A, 204Bare in the inflated state. More specifically, the inner balloon 204Aincludes an inner balloon diameter 204AD when the inner balloon 204A isin the inflated state, and the outer balloon 204B includes an outerballoon diameter 204BD when the outer balloon 204B is in the inflatedstate, with the outer balloon diameter 204BD being different than, i.e.greater than, the inner balloon diameter 204AD. In certain non-exclusivealternative embodiments, the outer balloon diameter 204BD when in theinflated state can be at least approximately 1%, 2%, 3%, 5%, 7%, 10%,12%, 15%, 17%, 20%, 22%, 25%, 27%, 30%, 32%, 35%, 37%, 40%, 42%, 45%,47% or 50% greater than the inner balloon diameter 204AD when the innerballoon 204A is also in the inflated state. Alternatively, thedifference between the outer balloon diameter 204BD of the outer balloon204B and the inner balloon diameter 204AD of the inner balloon 204A canbe different than the values noted above.

It is appreciated that in this embodiment, the balloons 204A, 204B canalso have different shapes from one another and/or be formed fromdifferent materials from one another, e.g., with different compliancesand/or different expansion rates, to further assist in the creation ofthe interstitial space 246A between the balloons 204A, 204B.

The energy guides 222A are configured to guide energy from the energysource 124 (illustrated in FIG. 1) to induce formation of plasma-inducedbubble(s) 134 (illustrated in FIG. 1) in the balloon fluid 232 withinthe balloon interior 246 of the outer balloon 204B and/or within theinterstitial space 246A between the balloons 204A, 204B, e.g., via aplasma generator 133 (illustrated in FIG. 1) located at or near theguide distal end 222D of the respective energy guide 222A. The formationof plasma-induced bubble(s) 134 imparts pressure waves and/or fractureforces upon the treatment site 106 (illustrated in FIG. 2A). Suchpressure waves and/or fracture forces are utilized to break apart thevascular lesions 106A (illustrated in FIG. 2A) at specific preciselocations within the heart valve 108 at the treatment site 106. Moreparticularly, by selectively positioning the balloon assembly 204adjacent to the treatment site 106, each of the energy guides 222A canbe applied to break up the calcified vascular lesions 106A in adifferent precise location at the treatment site 106.

It is further appreciated that in some embodiments, the inner balloon204A and the outer balloon 204B can be inflated to different inflationpressures, i.e. with the inner balloon 204A pressurized at a higherinflation pressure than the outer balloon 204B to improve the energytransfer by better directing the energy into the vascular lesions 106Aat the treatment site 106. More specifically, the improved energytransfer is achieved by keeping the balloon wall 230 of the innerballoon 204A immovable at high pressure so that the energy is notabsorbed by movement of the balloon wall 230 of the inner balloon 204A,but rather is directed in a generally outward direction to the balloonwall 230 of the outer balloon 204B positioned at the treatment site 106.

It is appreciated that bubble energy transfer from the energy guide 222Aand/or the plasma generator 133 to the calcified vascular lesion 106A atthe treatment site 106 is further enhanced as the balloon assembly 204is expanded by keeping the position of the energy guides 222A and/or theplasma generators 133 close to the treatment site 106 as the diameter ofthe heart valve 108 expands during valvuloplasty treatment.

As shown in this embodiment, the energy guides 222A can be coupled toand/or secured to an outer surface 204S of the inner balloon 204A, e.g.,with the guide distal end 222D of the energy guide 222A positionedsubstantially directly adjacent to the outer surface 204S of the innerballoon 204A. The energy guides 222A can be coupled to and/or secured tothe outer surface 204S of the inner balloon 204A in any suitable manner.For example, in one non-exclusive embodiment, the energy guides 222A canbe secured to the outer surface 204S of the inner balloon 204A with anadhesive material. Alternatively, the energy guides 222A can be coupledto and/or secured to the outer surface 204S of the inner balloon 204A inanother suitable manner. Still alternatively, in other embodiments, theenergy guides 222A can be positioned such that the guide distal end 222Dof the energy guide 222A is positioned spaced apart from the outersurface 204S of the inner balloon 204A.

FIG. 3 is a simplified cutaway view of a portion of the heart valve 108,and a portion of another embodiment of the catheter system 300 includinganother embodiment of the valvular lithoplasty balloon assembly 304. Theballoon assembly 304 is again configured to be selectively positionedadjacent to the valve wall 108A and/or between adjacent leaflets 108B(illustrated in FIG. 1) within the heart valve 108.

The balloon assembly 304 is substantially similar to what has beenillustrated and described in relation to the previous embodiments. Forexample, in this embodiment, the balloon assembly 304 again includes aninner balloon 304A and an outer balloon 304B, which is positioned tosubstantially, if not entirely, encircle the inner balloon 304A. Statedin another manner, the balloon assembly 304 includes the outer balloon304B, and the inner balloon 304A that is positioned at leastsubstantially, if not entirely, within the outer balloon 304B. Duringuse of the catheter system 300, the outer balloon 304B can again bepositioned adjacent to the valve wall 108A and/or on or between adjacentleaflets 108B within the heart valve 108 at the treatment site 106(illustrated in FIG. 1). The balloon assembly 304 is also illustrated asbeing positioned about the guide shaft 318, which provides the conduitthrough which the guidewire 312 extends, in this non-exclusiveimplementation.

Additionally, the balloons 304A, 304B of the balloon assembly 304 canagain be coupled to and/or secured to the catheter shaft 110(illustrated in FIG. 1) and the guide shaft 318 and/or to one another ina manner substantially similar to what has been described herein above.

Each balloon 304A, 304B can again include a balloon wall 330 thatdefines a balloon interior 346, and that is configured to receive theballoon fluid 132 (illustrated in FIG. 1) within the balloon interior346 of each balloon 304A, 304B and/or within the interstitial space 346Abetween the balloons 304A, 304B. Each balloon 304A, 304B can thus beselectively inflated with the balloon fluid 132 to expand from thedeflated state to the inflated state (as shown in FIG. 3).

In this embodiment, the interstitial space 346A can again be createdbetween the balloons 304A, 304B by one or more of having the balloons304A, 304B have different diameters than one another when in theinflated state; having the balloons 304A, 304B be of different shapesfrom one another when in the inflated state; and having the balloons304A, 304B be formed from different materials from one another so thatthey have different compliance and/or different expansion rates as theballoons 304A, 304B are moved to the inflated state.

FIG. 3 also illustrates the one or more energy guides 322A (four energyguides 322A are shown in FIG. 3) that can be positioned at least in partwithin the balloon interior 346 of the outer balloon 304B and/or withinthe interstitial space 346A between the balloons 304A, 304B. Moreparticularly, as shown, the guide distal end 322D of each of the energyguides 322A is shown as being positioned within the balloon interior 346of the outer balloon 304B and/or within the interstitial space 346Abetween the balloons 304A, 304B. Although four energy guides 322A arespecifically illustrated in FIG. 3, it is appreciated that the cathetersystem 300 can include any suitable number of energy guides 322A, whichcan also be greater than four or less than four energy guides 322A.Additionally, the energy guides 322A can have any desired spacingrelative to one another about the inner balloon 304A.

Similar to the previous embodiments, the energy guides 322A are againconfigured to guide energy from the energy source 124 (illustrated inFIG. 1) to induce formation of plasma-induced bubble(s) 134 (illustratedin FIG. 1) in the balloon fluid 132 within the balloon interior 346 ofthe outer balloon 304B and/or within the interstitial space 346A betweenthe balloons 304A, 304B, e.g., via a plasma generator 133 (illustratedin FIG. 1) located at or near the guide distal end 322D of therespective energy guide 322A. The formation of plasma-induced bubble(s)134 imparts pressure waves and/or fracture forces upon the treatmentsite 106. Such pressure waves and/or fracture forces are utilized tobreak apart the vascular lesions 106A (illustrated in FIG. 1) atspecific precise locations within the heart valve 108 at the treatmentsite 106. More particularly, by selectively positioning the balloonassembly 304 adjacent to the treatment site 106, each of the energyguides 322A can be applied to break up the calcified vascular lesions106A in a different precise location at the treatment site 106.

It is further appreciated that in some embodiments, the inner balloon304A and the outer balloon 304B can be inflated to different inflationpressures, i.e. with the inner balloon 304A pressurized at a higherinflation pressure than the outer balloon 304B to improve the energytransfer by better directing the energy into the vascular lesions 106Aat the treatment site 106. More specifically, the improved energytransfer is achieved by keeping the balloon wall 330 of the innerballoon 304A immovable at high pressure so that the energy is notabsorbed by movement of the balloon wall 330 of the inner balloon 304A,but rather is directed in a generally outward direction to the balloonwall 330 of the outer balloon 304B positioned at the treatment site 106.Bubble energy transfer from the energy guide 322A and/or the plasmagenerator 133 to the calcified vascular lesion 106A at the treatmentsite 106 is further enhanced as the balloon assembly 304 is expanded bykeeping the position of the energy guides 322A and/or the plasmagenerators 133 close to the treatment site 106 as the diameter of theheart valve 108 expands during valvuloplasty treatment.

As shown in this embodiment, the energy guides 322A can be positionedspaced apart from an outer surface 304S of the inner balloon 304A, e.g.,with the guide distal end 322D of the energy guide 322A positionedspaced apart from the outer surface 304S of the inner balloon 304A. Theenergy guides 3222A can be positioned spaced apart from the outersurface 304S of the inner balloon 304A in any suitable manner. Forexample, in some non-exclusive embodiments, the energy guides 322A canbe secured to and/or positioned on a guide support structure 360 that ismounted on the outer surface 304S of the inner balloon 304A. In one suchembodiment, the guide support structure 360 can be provided in the formof a nitinol scaffold that supports the guide distal end 322D of therespective energy guide 322A spaced apart from the outer surface 304S ofthe inner balloon 304A. Alternatively, the guide support structure 360can have a different design and/or the energy guides 322A can bemaintained spaced apart from the outer surface 304S of the inner balloon304A in a different manner.

FIG. 4 is a simplified side view of a portion of a fluid flow system 470usable within the catheter system 400. In particular, the fluid flowsystem 470 is configured to provide and/or direct the balloon fluid 132(illustrated in FIG. 1) into each of the inner balloon 404A and theouter balloon 404B of the balloon assembly 404. FIG. 4 also illustratesthe catheter shaft 410, the guide shaft 418 and the guidewire 412 of thecatheter system 400.

The design of the fluid flow system 470 can be varied to suit thespecific requirements of the catheter system 400. In certainembodiments, the fluid flow system 470 can include a first flow system472A that is configured to provide and/or direct the balloon fluid 132into the inner balloon 404A, and a second flow system 472B that isconfigured to provide and/or direct the balloon fluid 132 into the outerballoon 404B.

The design of each of the first flow system 472A and the second flowsystem 472B can be substantially similar to one another. Morespecifically, in the embodiment illustrated in FIG. 4, the first flowsystem 472A includes a first fluid pump 474A, a first inflation conduit476A, and a first seal assembly 478A, and the second flow system 472Bincludes a second fluid pump 474B, a second inflation conduit 476B, anda second seal assembly 478B. Alternatively, the first flow system 472Aand/or the second flow system 472B can include more components or fewercomponents than those specifically illustrated and described in relationto FIG. 4.

As shown, the first fluid pump 474A is configured to pump the balloonfluid 132 through the first fluid conduit 476A and into the ballooninterior 146 (illustrated in FIG. 1) of the inner balloon 404A. Thefirst seal assembly 478A can seal the connection of the first fluidconduit 476A into the balloon interior 146 of the inner balloon 404A.The first seal assembly 478A can have any suitable design for purposesof sealing the connection of the first fluid conduit 476A into theballoon interior 146 of the inner balloon 404A.

Similarly, the second fluid pump 474B is configured to pump the balloonfluid 132 through the second fluid conduit 476B and into the ballooninterior 146 (illustrated in FIG. 1) of the outer balloon 404B. Thesecond seal assembly 478B can seal the connection of the second fluidconduit 476B into the balloon interior 146 of the outer balloon 404B.The second seal assembly 478B can have any suitable design for purposesof sealing the connection of the second fluid conduit 476B into theballoon interior 146 of the outer balloon 404B.

In alternative embodiments, the fluid flow system 470 can be configuredto include a single fluid pump that is utilized to pump the balloonfluid 132 through each of the first fluid conduit 476A and into theballoon interior 146 of the inner balloon 404A, and the second fluidconduit 476B and into the balloon interior 146 of the outer balloon404B. More particularly, in such alternative embodiments, the singlefluid pump can be provided with two pressure-regulated flow valves foreach balloon 404A, 404B.

It should be noted that, as used in this specification and the appendedclaims, the singular forms “a,” “an,” and “the” include plural referentsunless the content and/or context clearly dictates otherwise. It shouldalso be noted that the term “or” is generally employed in its senseincluding “and/or” unless the content or context clearly dictatesotherwise.

It should also be noted that, as used in this specification and theappended claims, the phrase “configured” describes a system, apparatus,or other structure that is constructed or configured to perform aparticular task or adopt a particular configuration. The phrase“configured” can be used interchangeably with other similar phrases suchas arranged and configured, constructed and arranged, constructed,manufactured and arranged, and the like.

The headings used herein are provided for consistency with suggestionsunder 37 CFR 1.77 or otherwise to provide organizational cues. Theseheadings shall not be viewed to limit or characterize the invention(s)set out in any claims that may issue from this disclosure. As anexample, a description of a technology in the “Background” is not anadmission that technology is prior art to any invention(s) in thisdisclosure. Neither is the “Summary” or “Abstract” to be considered as acharacterization of the invention(s) set forth in issued claims.

The embodiments described herein are not intended to be exhaustive or tolimit the invention to the precise forms disclosed in the followingdetailed description. Rather, the embodiments are chosen and describedso that others skilled in the art can appreciate and understand theprinciples and practices. As such, aspects have been described withreference to various specific and preferred embodiments and techniques.However, it should be understood that many variations and modificationsmay be made while remaining within the spirit and scope herein.

It is understood that although a number of different embodiments of thecatheter systems have been illustrated and described herein, one or morefeatures of any one embodiment can be combined with one or more featuresof one or more of the other embodiments, provided that such combinationsatisfies the intent of the present invention.

While a number of exemplary aspects and embodiments of the cathetersystems have been discussed above, those of skill in the art willrecognize certain modifications, permutations, additions andsub-combinations thereof. It is therefore intended that the followingappended claims and claims hereafter introduced are interpreted toinclude all such modifications, permutations, additions andsub-combinations as are within their true spirit and scope, and nolimitations are intended to the details of construction or design hereinshown.

What is claimed is:
 1. A catheter system for treating a treatment sitewithin or adjacent to a heart valve within a body of a patient, thecatheter system comprising: an energy source that generates energy; anenergy guide that is configured to receive energy from the energysource; and a balloon assembly that is positionable adjacent to thetreatment site, the balloon assembly including an outer balloon and aninner balloon that is positioned substantially within the outer balloon,each of the balloons having a balloon wall that defines a ballooninterior, each of the balloons being configured to retain a balloonfluid within the balloon interior, the balloon wall of the inner balloonbeing positioned spaced apart from the balloon wall of the outer balloonto define an interstitial space therebetween; wherein a portion of theenergy guide is positioned within the interstitial space between theballoons to generate plasma-induced bubble formation in the balloonfluid within the interstitial space upon the energy guide receivingenergy from the energy source.
 2. The catheter system of claim 1 whereineach of the balloons is selectively inflatable with the balloon fluid toexpand to an inflated state so that the balloon wall of the innerballoon is spaced apart from the balloon wall of the outer balloon todefine the interstitial space therebetween.
 3. The catheter system ofclaim 2 wherein when the balloons are in the inflated state, the outerballoon is configured to be positioned substantially adjacent to thetreatment site.
 4. The catheter system of claim 2 wherein when theballoons are in the inflated state, the inner balloon has an innerballoon diameter, and the outer balloon has an outer balloon diameterthat is at least approximately 5% greater than the inner balloondiameter.
 5. The catheter system of claim 2 wherein when the balloonsare in the inflated state, the inner balloon is inflated to a greaterinflation pressure than the outer balloon.
 6. The catheter system ofclaim 1 wherein the inner balloon is made from a first material, andwherein the outer balloon is made from a second material that isdifferent from the first material.
 7. The catheter system of claim 6wherein the first material has a first compliance, and the secondmaterial has a second compliance that is greater than the firstcompliance so that the outer balloon expands at a faster rate than theinner balloon when the balloons are expanded to an inflated state. 8.The catheter system of claim 1 wherein the first material isnon-compliant, and wherein the second material is semi-compliant.
 9. Thecatheter system of claim 1 wherein the first material is non-compliant,and wherein the second material is compliant.
 10. The catheter system ofclaim 1 wherein the first material is semi-compliant, and wherein thesecond material is compliant.
 11. The catheter system of claim 1 furthercomprising a guide support structure that is mounted on an outer surfaceof the inner balloon, and wherein the energy guide is positioned on theguide support structure so that the energy guide is positioned spacedapart from the outer surface of the inner balloon.
 12. The cathetersystem of claim 1 further comprising a plasma generator that ispositioned near a guide distal end of the energy guide, the plasmagenerator being configured to generate a plasma-induced bubble in theballoon fluid within the interstitial space between the balloons. 13.The catheter system of claim 1 wherein the plasma-induced bubbleformation imparts pressure waves upon the balloon wall of the outerballoon adjacent to the treatment site.
 14. The catheter system of claim1 wherein the energy source generates pulses of energy that are guidedalong the energy guide into the interstitial space between the balloonsto generate a plasma-induced bubble in the balloon fluid within theinterstitial space between the balloons.
 15. The catheter system ofclaim 1 wherein the energy source is a laser source that provides pulsesof laser energy.
 16. The catheter system of claim 1 wherein the energyguide includes an optical fiber.
 17. The catheter system of claim 1wherein the energy source is a high voltage energy source that providespulses of high voltage.
 18. The catheter system of claim 1 wherein theenergy guide includes an electrode pair including spaced apartelectrodes that extend into the interstitial space between the balloons,and pulses of high voltage from the energy source are applied to theelectrodes and form an electrical arc across the electrodes.
 19. Thecatheter system of claim 1 further comprising a plurality of energyguides that are configured to receive energy from the energy source, anda portion of each of the plurality of energy guides that receive theenergy is positioned within the interstitial space between the balloonsto generate plasma-induced bubble formation in the balloon fluid withinthe interstitial space.
 20. A method for treating a treatment sitewithin or adjacent to a heart valve that uses the catheter system ofclaim
 1. 21. A catheter system for treating a treatment site within oradjacent to a heart valve within a body of a patient, the cathetersystem comprising: an energy source that generates energy; an energyguide that is configured to receive energy from the energy source; and aballoon assembly that is positionable adjacent to the treatment site,the balloon assembly including an outer balloon and an inner balloonthat is positioned substantially within the outer balloon, the innerballoon being made from a first material having a first compliance andthe outer balloon being made from a second material that is differentfrom the first material, the second material having a second compliancethat is greater than the first compliance, each of the balloons having aballoon wall that defines a balloon interior, each of the balloons beingconfigured to retain a balloon fluid within the balloon interior, theballoon wall of the inner balloon being positioned spaced apart from theballoon wall of the outer balloon to define an interstitial spacetherebetween, each of the balloons being inflatable with the balloonfluid to expand to an inflated state, wherein when the balloons are inthe inflated state, (i) the inner balloon has an inner balloon diameter,(ii) the outer balloon has an outer balloon diameter that is at leastapproximately 5% greater than the inner balloon diameter, and (iii) theinner balloon is inflated to a greater inflation pressure than the outerballoon; wherein a portion of the energy guide is positioned within theinterstitial space between the balloons to generate plasma-inducedbubble formation in the balloon fluid within the interstitial space uponthe energy guide receiving energy from the energy source.